4. Determine the percent transmittance of ß-carotene, C40H56 that has an absorbance of 0.5 when analyse using a UV-Visible spectrophotometer. A. 6.83% B. 31.6% C. 0.32% D. 68.3% 5. The equation of Beer Lambert's Law is A = abc. If the 'b' is distance, 'a' is absorptivity, and 'A' is absorbance, what does the 'c' represent? A. Intensity B. Analyte concentration C. Analyte transmittance D. Frequency 6. All the following is an example of photon detectors EXCEPT: A. Vacuum phototube B. Silicon photodiodes C. Bolometers D. Photomultiplier tubes 7. C=0 bond stretch occurs at 1750 cm¹ and C-O stretch occurs at 1100 cm¹ because: A. The C-O has a single bond which is a stronger bond, so it vibrates at a higher frequency than the C=0. B. The C-O has a single bond which is a stronger bond, so it vibrates at a lower frequency than the C=0. C. The C=0 has a double bond which is a stronger bond, so it vibrates at a lower frequency than the C-O. D. The C=O has a double bond which is a stronger bond, so it vibrates at a higher frequency than the C-O.

4. Determine the percent transmittance of ß-carotene, C40H56 that has an absorbance of 0.5 when analyse using a UV-Visible spectrophotometer. A. 6.83% B. 31.6% C. 0.32% D. 68.3% 5. The equation of Beer Lambert's Law is A = abc. If the 'b' is distance, 'a' is absorptivity, and 'A' is absorbance, what does the 'c' represent? A. Intensity B. Analyte concentration C. Analyte transmittance D. Frequency 6. All the following is an example of photon detectors EXCEPT: A. Vacuum phototube B. Silicon photodiodes C. Bolometers D. Photomultiplier tubes 7. C=0 bond stretch occurs at 1750 cm¹ and C-O stretch occurs at 1100 cm¹ because: A. The C-O has a single bond which is a stronger bond, so it vibrates at a higher frequency than the C=0. B. The C-O has a single bond which is a stronger bond, so it vibrates at a lower frequency than the C=0. C. The C=0 has a double bond which is a stronger bond, so it vibrates at a lower frequency than the C-O. D. The C=O has a double bond which is a stronger bond, so it vibrates at a higher frequency than the C-O.

Chemistry

10th Edition

ISBN:9781305957404

Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Publisher:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCoste

Chapter1: Chemical Foundations

Section: Chapter Questions

Problem 1RQ: Define and explain the differences between the following terms. a. law and theory b. theory and...

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prelab 2) please see attached
A student creates a sports drink by dissolving 5.0 g of powder in 250 mL of water. The green colour of the drink is due to the presence Green Dye X, which has a lambdamax of 630 nm. A calibration curve (absorbance versus concentration) at lambdamax is created for varying concentrations (mM) of Green Dye X which has the equation y = 26.4x. If 1.0 mL of the sports drink is diluted to 10. mL with water, then the absorbance is measured to be 0.450, what is the mass percent of Green Dye X in the drink powder if the molecular weight is 418.4 g mol-1?
A student creates a sports drink by dissolving 5.0 g of powder in 250 mL of water. The green colour of the drink is due to the presence Green Dye X, which has a lambdamax of 630 nm. A calibration curve (absorbance versus concentration) at lambdamax is created for varying concentrations (mM) of Green Dye X which has the equation y = 26.8x. If 1.0 mL of the sports drink is diluted to 10. mL with water, then the absorbance is measured to be 0.340, what is the mass percent of Green Dye X in the drink powder if the molecular weight is 418.4 g mol-1?
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